A Method for City-Wide PoI-Level Congestion Prediction via Assimilation of Actual and Simulation-Based PoI Congestion Data

• Published in: 2024 IEEE International Conference on Smart Computing (SMARTCOMP) pp. 39 - 46
• Main Authors: Sakagami, Haruka, Yamada, Osamu, Matsuda, Yuki, Suwa, Hirohiko, Yasumoto, Keiichi
• Format: Conference Proceeding
• Language: English
• Published: IEEE 29.06.2024
• Subjects: Accuracy; digital twin; Fluids; Human flow simulation; PoI congestion; Probability; Simulation; Sociology; synthetic population data; Urban areas; Vectors
• ISSN: 2693-8340
• DOI: 10.1109/SMARTCOMP61445.2024.00027

Regulating human flow is essential to reducing congestion in areas where people gather. A digital twin that realistically simulates human flow helps for this purpose. To realize a realistic human flow simulation mechanism, it is essential to take into account people's attributes. However, existing simulation methods use only location-specific information to predict people's behavior, thus do not reflect the routines that appear in people's actual lives. In this paper, we propose a human flow simulation using synthetic population data that help extract the attributes of people living in a target area. In the proposed method, we simulate the movement of people with each attribute like office workers, students, etc. every 15 minutes using the synthetic population data and the hourly transition probability matrix between PoIs (Points of Interest) by computing the transition probability matrix from hourly PoI-level congestion (people count) in the target area using people trajectory data included in the point-type fluid population data commercially available and applying a Markov chain to the congestion. The proposed simulation mechanism is based on the data assimilation of the actual PoI congestion vector (how many people were staying in each PoI) obtained from the point-type fluid population data and the virtual PoI congestion vector generated from the prediction of people's movement using the attribute information in the synthetic population data at regular time intervals. The data are assimilated at regular intervals to obtain highly accurate PoI-level congestion forecasts. The results of the mobility simulation for office workers showed that the maximum cosine similarity with the actual PoI congestion was 0.96 after 12 hours even when the actual PoI congestion vector is known only for a part of the area (one mesh).